KR20190037614A - Apparatus for cutting trash in water - Google Patents

Abstract

The present invention relates to an underwater foreign material crushing device comprising: a housing which has an internal space and includes a seating plate combined thereto by crossing the lower part of the internal space and provided with an opening unit; an upper flow pipe which is connected to the upper part of a side wall of the housing and has a water draining unit mounted thereto; a lower flow pipe which is connected to the bottom surface of the housing and has a water supplying unit mounted thereto; a strainer net which has a cylindrical shape, of which the bottom end is seated on the top surface of the seating plate, and the top end is seated on the ceiling surface of the housing; a rotary shaft which has a rotary structure and stands vertically in the inside of the strainer net; a plurality of paddles which are combined with the rotary shaft in order to be closely attached to the inner surface of the strainer net; and a driving motor which rotates the rotary shaft so that the paddles can rotate while maintaining the attached state to the inner surface of the strainer net. Therefore, the underwater foreign material crushing device can provide user convenience by removing the foreign materials accumulated therein even without disassembling or assembling the device.

Description

[0001] Apparatus for cutting trash in water [

The present invention relates to a crushing apparatus for crushing foreign substances contained in water, and more particularly, to a crushing apparatus for an underwater object which can increase the treatment flow rate per unit time and is capable of backwashing and is easy to maintain and repair.

In general, pools and sewage contain various foreign substances such as hair, vinyl, and wood chips. When such foreign matter enters the inside of the pump, the pump is damaged and the operation is interrupted.

In order to solve such a problem, a foreign matter cutting device for crushing foreign matter contained in water and flowing the foreign matter by a pump has been proposed in various structures.

In the conventionally proposed foreign matter cutting apparatus, two or more pulverizing screws are arranged in parallel on a flow path through which water flows, so that the foreign substances contained in the water are crushed by the crushing screw, or a cutting blade is installed And cuts the foreign matter finely with the cutting blade.

However, in the conventional foreign matter cutting apparatus configured as described above, since the flow speed is significantly reduced when the pulverizing screw or the cutting blade is operated, there is a limit to increase the processing flow rate per unit time, and when the foreign matter is entangled in the pulverizing screw or the cutting blade, The screw or the cutting blade may not be operated normally. Therefore, when the foreign matter is entangled in the pulverizing screw or the cutting blade, it is necessary to clean the pulverizing screw or the cutting blade after disassembling the foreign material cutting device. Thus, it takes a long time to disassemble and reassemble the foreign material cutting device .

KR 10-1497052 B1

Disclosure of Invention Technical Problem [8] The present invention has been proposed in order to solve the above-mentioned problems. It is an object of the present invention to provide a structure for crushing foreign matters without greatly disturbing the flow of water, It is an object of the present invention to provide a foreign substance crushing apparatus.

To achieve these objects and other advantages and in accordance with the purpose of the invention, as embodied and broadly described herein, there is provided a device for crushing underwater foreign matter, comprising: a housing having an inner space and having a seating plate coupled to a lower side of an inner space; An upper side flow pipe connected to an upper portion of a side wall of the housing and having a drain portion mounted thereon; A lower side flow pipe connected to a bottom surface of the housing and having a water supply portion mounted thereon; A strainer mesh formed in a cylindrical shape and having a lower end seated on an upper surface of the seat plate and an upper end seated on a ceiling surface of the housing; A rotating shaft that is vertically erected inside the strainer net in a rotatable structure; A plurality of paddles coupled to the rotating shaft to closely contact the inner surface of the strainer nets; And a driving motor that rotates the rotating shaft so that the paddles are rotated while maintaining a state in which the paddles are in close contact with the inner surface of the strainer nets.

Wherein the paddle is provided with an insertion hole into which the end of the fastening bar is inserted, and the paddle is inserted into the paddle in a direction in which the paddle is in close contact with the inner surface of the strainer nets, And a spring for applying an elastic force.

The spring is applied as a coil spring which is coupled to surround the rotating shaft of the fastening bar and the paddle.

The plurality of paddles are arranged radially about the rotating shaft.

The strainer nets are made of stainless steel and the paddles are made of engineering plastics.

And a water level sensor for sensing a water level inside the housing, wherein the drive motor is configured to rotate the rotating shaft when the water level inside the housing reaches a preset height.

The seating plate has a shaft fastening hole into which the lower end of the rotating shaft is rotatably inserted, and the opening is radially arranged around the shaft fastening hole.

A second pressure sensor for measuring the water pressure of the upper side flow pipe, a reverse flow water inflow part for supplying reverse side water to the inside of the housing through the upper side flow pipe, And a drain portion for discharging backwash water in the housing through the lower side flow pipe. When the water pressure of the lower side flow pipe is higher than a predetermined pressure range of the upper side flow pipe, do.

The upper channel pipe extends in a horizontal direction, the drainage unit is installed at an end of the upper channel pipe, and the reverse water pipe inlet is installed at a point branched vertically from the upper channel pipe.

The lower flow pipe extends vertically downward, the water supply unit is installed at a position where the water supply unit is branched from the lower flow pipe in a horizontal direction, and the drain unit is installed at a lower end of the lower flow pipe.

The apparatus for crushing foreign matter in water according to the present invention can increase the treatment flow rate per unit time since the structure for crushing the foreign substances contained in water does not significantly disturb the flow of water, It is advantageous in that it is easy to use because the foreign matter can be removed.

1 is a schematic view of an apparatus for crushing underwater objects according to the present invention.
2 is an exploded perspective view showing a structure in which a rotating shaft and paddles are mounted inside the strainer nets.
3 is a horizontal sectional view showing a structure in which paddles are connected to a rotating shaft.
4 is a plan view of the seating plate.
FIG. 5 and FIG. 6 show the state of use of the apparatus for separating underwater foreign material according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic view of an apparatus for crushing underwater objects according to the present invention, FIG. 2 is an exploded perspective view showing a structure in which a rotating shaft and paddles are mounted inside a strainer net, FIG. And Fig. 4 is a plan view of the seating plate.

The apparatus for crushing foreign matter in the water according to the present invention is characterized in that, in order to prevent foreign matter contained in water from flowing into the pump when the large amount of water is transferred to the pump, And is finely crushed, but is configured to be easy to maintain and repair without deteriorating the fluidity of water.

That is, according to the present invention, the apparatus for crushing underwater foreign matter comprises a housing 100 having a chamber plate having an internal space, a housing 100 having a seating plate 110 formed to cross the lower side of the internal space and having an opening 114 formed therein, An upper channel pipe 200 connected to an upper portion of a side wall of the housing 100 and to which a drainage unit 210 is mounted, a lower channel pipe 200 connected to a bottom surface of the housing 100, A strainer net (400) having a cylindrical shape and having a lower end seated on an upper surface of the seating plate (110) and an upper end seated on a ceiling surface of the housing (100) A plurality of paddles 600 coupled to the rotating shaft 500 so as to be in close contact with an inner surface of the strainer nets 400; Is in close contact with the inner surface of the strainer nets 400 And a driving motor 700 that rotates the rotating shaft 500 so as to rotate while maintaining the rotation shaft 500 as a basic component. At this time, the lower end of the rotary shaft 500 is inserted into the shaft fastening hole 112 formed in the seating plate 110 in a rotatable manner, and can be rotated by the driving motor 700 only.

The water supplied from outside through the water supply unit 310 flows into the housing 100 through the lower flow path pipe 300 and then flows into the strainer nets 400 through the opening 114 of the seat plate 110 ≪ / RTI > At this time, since the opening 114 is formed only at a portion corresponding to the inner space of the strainer nets 400, all the water that has passed through the opening 114 of the seating plate 110 flows into the strainer nets 400. In this case, the opening 114 is preferably radially arranged around the shaft coupling hole 112 so that water can be uniformly introduced into the entire inner space of the strainer nets 400.

The strainer nets 400 may include various foreign substances such as hair, vinyl, wood pieces, etc., and the strainer nets 400 may be configured to prevent the foreign substances having a predetermined size or more from passing through the strainer nets 400 The water introduced into the strainer nets 400 is primarily filtered by the strainer nets 400 and then discharged to the drain 210 through the upper flow pipe 200.

At this time, if the foreign substances filtered by the strainer nets 400 are accumulated in the strainer nets 400, the foreign substances block the holes of the strainer nets 400 and the water can not flow normally. Accordingly, the apparatus for crushing underwater objects according to the present invention is configured such that the foreign matters are crushed between the inner side of the strainer and the paddle 600.

The water introduced into the strainer nets 400 flows in a circular shape due to the rotation of the rotating shaft 500. The foreign substances contained in the water are adhered to the inner surface of the strainer nets 400 by centrifugal force. The plurality of paddles 600 contacting the inner surface of the strainer nets 400 are rotated together with the rotating shaft 500. The foreign substances closely adhered to the inner surfaces of the strainer nets 400 pass through the strainer nets 400, And then discharged through the strainer nets 400 to the drainage unit 210.

The foreign matter crushed between the strainer nets 400 and the paddle 600 is split into small pieces so as to pass through the strainer nets 400. Even if a foreign matter piece discharged through the drainage part 210 flows into the inside of the pump, And no damage or failure occurs. At this time, the smaller the eyes of the strainer nets 400, the smaller the size of the pieces of foreign matter discharged through the drain portion 210. When the eyes of the strainer nets 400 are excessively small, the strainer nets 400 are very easily The mesh size of the strainer nets 400 can be varied depending on various uses such as the grinding performance of the underwater particle grinder according to the present invention and the specifications of the pump, It is preferable to select appropriately according to the conditions.

In other words, the strainer nets 400 are preferably made of a metal which is highly resistant to corrosion and is resistant to wear and tear, that is, stainless steel or the like, even if the foreign matter is crushed for a long time. In this case, when the stainless steel is manufactured up to the paddle 600 as well as the strainer nets 400, a large noise may be generated during the foreign matter crushing process, and the strainer nets 400 and the paddle 600 may be damaged. Therefore, it is desirable that the paddle 600 is made of high-strength synthetic resin such as engineering plastic.

A plurality of paddles 600 are mounted on one rotary shaft 500. When the paddle 600 is mounted on only one side of the rotary shaft 500 and the rotary shaft 500 can not rotate stably May occur. Accordingly, the paddles 600 are preferably radially arranged around the rotary shaft 500 as shown in FIGS. At this time, the mounting number and the arrangement angle of the paddle 600 can be freely selected according to various conditions such as the use of the grinding apparatus according to the present invention and the specification of the paddle 600.

As described above, when the paddle 600 is made of synthetic resin and the strainer nets 400 are made of metal, the paddle 600 is worn when the paddle 600 rubs against the strainer nets 400 for a long time, The paddle 600 may not be squeezed on the inner surface of the strainer nets 400 and the performance of crushing the foreign substances may be deteriorated.

Therefore, it is preferable that the paddle 600 is not fixedly coupled to the rotating shaft 500 but is mounted so as to be resiliently attached to the inner surface of the strainer nets 400. That is, the rotary shaft 500 includes a plurality of fastening bars 510 extending in the horizontal direction, and an insertion hole 610 through which the end of the fastening bar 510 is inserted is formed in the paddle 600 And a spring 620 for applying an elastic force to the paddle 600 in a direction in which the paddle 600 is in close contact with the inner surface of the strainer nets 400.

The paddle 600 is mounted so as to be freely movable in the longitudinal direction of the fastening bar 510, that is, in the horizontal direction, and is elastically brought into close contact with the inner surface of the strainer nets 400 by the spring 620, Even if it is worn by friction with the strainer nets 400, it can always be maintained in a state of being pressed on the inner surface of the strainer nets 400.

The spring 620 elastically pressing the paddle 600 to the strainer nets 400 elastically presses the paddles 600 outwardly (more specifically toward the inner side of the strainer nets 400) It can be applied to any kind of elastomer. The spring 620 may be a coil spring that wraps the paddle 600 between the rotary shaft 500 and the paddle 600 of the fastening bar 510 so as to elastically press the paddle 600 along the longitudinal direction of the fastening bar 510. [ 620). The spring 620 is installed in a compressed state between the rotary shaft 500 and the paddle 600 so that the paddle 600 can always maintain a state of being in close contact with the inner surface of the strainer nail 400 do.

The foreign matter crushing operation of the paddle 600 and the strainer nets 400 is effective only when water is completely filled in the housing 100. Therefore, the apparatus for pulverizing underwater according to the present invention further includes a water level sensor 220 for sensing the water level inside the housing 100. The water level of the interior of the housing 100 is preset in the driving motor 700 It is preferable that the rotation shaft 500 is controlled to be rotated when the water level sensor 220 senses the water level inside the housing 100 as full. The detailed description of the internal structure and operating principle of the full-water detector 220 will be omitted since the full-water detector 220 for detecting whether or not the full-water detector 220 is fully commercialized has various structures in the related art.

Even if the paddle 600 and the strainer nets 400 crush the foreign matters very finely, if the elapsed time elapses, the strainer nets 400 may be clogged with foreign substances. If the strainer nets 400 are clogged with foreign substances, the water supplied into the strainer nets 400 can not be discharged smoothly. Therefore, it is necessary to clean the strainer nets 400.

In this case, when the strainer nets 400 are cleaned after all the housings 100 are disassembled, it takes a long time to clean the strainer nets 400, There is a problem that it can not be crushed.

Therefore, the apparatus for pulverizing underwater according to the present invention can be configured to clean the strainer nets 400 in a backwashing manner without disassembling the housing 100. The apparatus for pulverizing underwater according to the present invention comprises a first pressure sensor 810 for measuring the water pressure of the lower flow pipe 300 and a second pressure sensor 830 for measuring the water pressure of the upper flow pipe 200 A reverse water inflow part 230 for supplying reverse osmosis water to the inside of the housing 100 through the upper side flow path pipe 200 and a reverse osmosis inflow part 230 for supplying reverse osmosis water to the inside of the housing 100 through the lower side flow path pipe 300, And a drain part 320 for discharging the reverse water.

When the strainer nets 400 are clogged, the water pressure on the side where the water is supplied (the lower side flow path pipe 300) becomes higher than the water pressure on the side where the water is drained (the upper side flow path pipe 200) If the water pressure is higher than the water pressure measured by the second pressure sensor 820, it is determined that the strainer nets 400 are blocked and the backwash is performed.

The process of backwashing in the process of pulverizing the foreign object in water will be described in detail with reference to FIG. 5 and FIG.

FIG. 5 and FIG. 6 show the state of use of the apparatus for separating underwater foreign material according to the present invention.

When the foreign object contained in the water is crushed by using the apparatus for crushing underwater according to the present invention, water is supplied to the inside of the housing 100 through the water supply unit 310 as shown in FIG. The water supplied to the inside of the housing 100 flows into the strainer nets 400 through the openings 114 of the seat plate 110 and is filtered while passing through the strainer nets 400, And the drainage unit 210, as shown in Fig.

At this time, the upper channel pipe 200 is extended in the horizontal direction and the drainage unit 210 is connected to the upper end of the upper channel pipe 200 so that the water passing through the strainer nets 400 can flow more smoothly. It is desirable to install. At this time, it is preferable that the countercleaning water inflow portion 230 is installed at a branching point in the vertical direction from the upper side flow pipe 200 so as not to be significantly affected by the flow pressure of water discharged along the upper side flow pipe 200 .

Meanwhile, when the strainer nets 400 are blocked to a certain level or more and the flow of water and the crushing of the foreign matter are not normally performed, the apparatus for crushing underwater according to the present invention may perform a backwash process for removing foreign substances blocking the strainer nets 400 .

That is, when the water pressure of the lower side flow pipe 300 is higher than the water pressure of the upper side flow pipe 200 by a predetermined range or more, it is determined that the strainer nets 400 are clogged, And supplies the backwash water to the inside of the housing 100 through the inflow portion 230.

The backwash water supplied to the inside of the housing 100 passes through the strainer nets 400 from the outside to the inside to remove foreign substances blocking the strainer nets 400. The foreign matter removed by the reverse osmosis water flows vertically downward And is discharged to the outside through the drain portion 320.

The lower flow pipe 300 extends vertically downward and the drain 320 extends to the lower end of the lower flow pipe 300 so that the foreign matter passing through the placement plate 110 can be discharged more quickly and smoothly. It is desirable to install. The water supply unit 310 is provided at a branching point in the horizontal direction from the lower flow pipe 300 so as to prevent the foreign matter passing through the lower flow pipe 300 from flowing into the water supply unit 310 side. desirable.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the scope of the present invention is not limited to the disclosed exemplary embodiments. It will also be appreciated that many modifications and variations will be apparent to those skilled in the art without departing from the scope of the present invention.

100: housing 110: seating plate
112: shaft fastening hole 114: opening
200: Upper side flow pipe 210:
220: full water detector 230: reverse water inlet
300: lower flow pipe 310:
320: drain part 400: strainer mesh
500: rotating shaft 510: fastening bar
600: Paddle 610: Insertion ball
620: spring 700: drive motor
810: first pressure sensor 820: second pressure sensor

Claims (10)

A housing having an inner space, the housing having a seating plate coupled to a lower side of the inner space and having an opening;
An upper side flow pipe connected to an upper portion of a side wall of the housing and having a drain portion mounted thereon;
A lower side flow pipe connected to a bottom surface of the housing and having a water supply portion mounted thereon;
A strainer mesh formed in a cylindrical shape and having a lower end seated on an upper surface of the seat plate and an upper end seated on a ceiling surface of the housing;
A rotating shaft that is vertically erected inside the strainer net in a rotatable structure;
A plurality of paddles coupled to the rotating shaft to closely contact the inner surface of the strainer nets; And
A driving motor that rotates the rotating shaft so that the paddles are rotated while maintaining a state in which the paddles are in close contact with the inner surface of the strainer nets;
Wherein the grinding device comprises: The method according to claim 1,
Wherein the rotary shaft includes a plurality of fastening bars extending in a horizontal direction,
An insertion hole into which the end of the fastening bar is inserted is formed in the paddle,
Further comprising a spring for applying an elastic force to the paddles in a direction in which the paddles are in close contact with the inner surface of the strainer nets. The method of claim 2,
Wherein the spring is a coil spring that is coupled to surround the rotating shaft of the fastening bar and the paddle. The method according to claim 1,
Wherein the plurality of paddles are radially arranged around the rotating shaft. The method according to claim 1,
Wherein the strainer nets are made of stainless steel and the paddles are made of engineering plastics. The method according to claim 1,
Wherein the seating plate has a shaft fastening hole into which the lower end of the rotating shaft is rotatably inserted, and the opening is radially arranged around the shaft fastening hole. The method according to claim 1,
Further comprising a water level sensor for sensing a water level inside the housing,
Wherein the driving motor is configured to rotate the rotating shaft when the water level inside the housing reaches a preset height. The method according to claim 1,
A second pressure sensor for measuring a water pressure of the upper side flow pipe, a reverse flow water inflow portion for supplying reverse side water to the inside of the housing through the upper side flow pipe, And a drain portion for discharging backwash water in the housing through the lower side flow pipe,
And backwash the strainer nets when the water pressure of the lower side flow pipe is higher than a predetermined range higher than the water pressure of the upper side flow pipe. The method of claim 8,
Wherein the upper flow pipe extends in the horizontal direction,
The drainage portion is installed at an end of the upper flow pipe,
And the backwash water inflow portion is installed at a point branched vertically from the upper side channel pipe. The method of claim 8,
Wherein the lower flow pipe extends vertically downward,
Wherein the water supply unit is installed at a branching point in the horizontal direction from the lower side flow pipe,
And the drain portion is installed at a lower end of the lower flow path pipe.

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